KR100420324B1 - Temperature control method for over the range - Google Patents

Abstract

The present invention relates to a temperature compensation method of a microwave oven with a hood, and more particularly, to a control method for temperature compensation at the time of convection temperature control of the microwave oven. The present invention is characterized in that when performing the convection function, by adjusting the temperature compensation value according to whether the vent motor is driven, a constant internal temperature control can be always performed regardless of the driving of the vent motor.

Description

Temperature control method for microwave oven with hood {Temperature control method for over the range}

The present invention relates to a temperature compensation method of a microwave oven with a hood, and more particularly, to a control method for temperature compensation at the time of convection temperature control of the microwave oven.

The microwave oven is equipped with a microwave function using microwave waves, a convection function for performing cooking by circulating the heat of the heater. In addition, in the case of a hood-use microwave oven, it has a vent function that operates to discharge the exhaust gas generated in the microwave oven itself or to exhaust the exhaust gas generated during cooking of the gas range to the outside.

As shown in FIG. 1, a conventional hood-use microwave oven includes a vent motor 20 at the top of the microwave oven. The vent motor 20 performs the same function as the indoor hood. That is, it is used for the purpose of exhausting the smoke | gas generated from the cooking apparatus 30 installed in the lower side of a microwave oven to the outside. Therefore, the vent motor 20 is selectively operated regardless of the driving of the microwave oven.

When the vent motor 20 is driven, as shown in FIG. 1, the smoke from the external cooking device 30 passes through the air flow path between the cooking chamber 10 and the external cavity 15 of the microwave oven. It is discharged to the rear side of the motor 20.

On the other hand, the vent motor 20 is configured to be controlled regardless of the operation of the microwave oven. Therefore, the on / off operation of the vent motor 20 can be controlled even when the microwave oven performs the convection function by the convection circulation and the microwave function by the microwave wave.

In addition, the cooking control by the temperature of the microwave oven, based on the temperature of the thermistor 25 is installed on one side of the cooking chamber 10 to sense the cooking chamber temperature. Therefore, when cooking is in progress, the sensing temperature of the thermistor 25 is read and used as a basic signal for cooking temperature control.

By the way, the temperature detected by the thermistor 25 is directly received from the food inside the cooking chamber 10 is a difference in the predetermined value. This is an error caused by conditions such as the performance of the thermistor 25 or an installation position. Therefore, when cooking the microwave, a predetermined value (value determined by the experiment) is added to the detection temperature of the thermistor 25, and the cooking is controlled by recognizing it as the actual cooking chamber 10 temperature.

On the other hand, as mentioned above, in addition to the microwave function, the microwave oven is further provided with a convection function for cooking by circulating the heat generated by the heater through the convection fan.

The convection function is a function of performing cooking while controlling the generated heat of the heater installed on the side or the upper portion of the cooking chamber to be circulated to the food through the convection fan. When performing the convection function, the operation of the vent motor 20 directly affects the temperature inside the cooking chamber 10.

That is, as shown in FIG. 2A, in a state in which the vent motor 20 is not operated, the temperature is sensed through the thermistor 25 and is applied to the food inside the cooking chamber 10 according to the sensing temperature. The temperature is almost equal to or similar to the preset value.

However, as shown in FIG. 2B, in a state in which the vent motor 20 operates, the temperature applied to the food inside the cooking chamber 10 in accordance with the temperature sensed through the thermistor 25 and the detection temperature. Many differences occur. That is, it is out of the range preset in FIG. 2A.

Nevertheless, since the conventional temperature control method of the microwave oven cannot determine such an error, temperature control is performed by a preset value regardless of whether the vent motor 20 is operated. Therefore, in the conventional microwave temperature control method, when the vent motor 20 operates, a problem occurs that an error occurs in the high temperature control condition while the sensing temperature of the thermistor 25 is changed.

When an error occurs in the high temperature control condition, the food is burned, and as a result, a problem that leads to dissatisfaction with the product occurs.

Accordingly, an object of the present invention is to provide a temperature compensation method for a microwave oven with a hood that can perform temperature compensation for the optimal cooking by varying the temperature control conditions according to the use of the vent motor in the hood microwave oven. Is in.

1 is a conceptual diagram of a typical hood combined microwave,

2A is an output waveform diagram showing a temperature control state of a microwave oven during a vent motor stop operation according to the prior art;

2B is an output waveform diagram showing a temperature control state of the microwave oven during the operation of the vent motor according to the prior art;

3 is a configuration diagram for controlling the temperature compensation in the hood combined microwave oven according to the present invention,

4 is an operation flowchart for the temperature compensation of the hood combined microwave oven according to the present invention,

Figure 5a is a temperature control table in the vent motor operating state in the microwave oven with hood according to the present invention,

Figure 5b is a temperature control table in the vent motor stationary state in a combined microwave oven according to the present invention.

Explanation of symbols on the main parts of the drawings

10: cooking chamber 15: external cavity

20: Vent motor 25: Thermistor

50: control unit 55: thermistor detection unit

60: memory 65: heater driving unit

70: convection fan drive unit 75: signal input unit

80: display unit 85: vent motor drive unit

The temperature compensation method of the hood combined microwave oven according to the present invention for achieving the above object is a hood combined microwave oven having a vent motor that is operated irrespective of the operation of the microwave oven for the indoor hood function, Setting a temperature compensation value 1 and a temperature compensation value 2 according to whether the vent motor is driven; Determining whether the vent motor is driven; Detecting an internal temperature of the cooking chamber through the temperature detector; And selecting one of the set temperature compensation values 1 and 2 according to whether the vent motor is driven, and performing temperature compensation on the detected temperature according to the selected temperature compensation value.

The temperature compensation step is characterized in that it is made until reaching the target temperature by cooking.

Hereinafter, with reference to the accompanying drawings will be described in detail with respect to the temperature compensation method of the microwave oven with hood according to the present invention.

3 is a configuration diagram for controlling the temperature compensation of the hood combined microwave oven according to the present invention. And the mechanical structure is demonstrated with reference to FIG.

As shown in FIG. 1, the hood-use microwave oven of the present invention includes a thermistor 25 for sensing a temperature inside the cooking chamber 10. The thermistor 25 is mounted on the upper side of the cooking chamber or one side of the side wall. The internal temperature of the cooking chamber detected by the thermistor 25 is detected through the thermistor detector 55 and applied to the controller 50 to be described later.

The controller 50 adjusts the cooking temperature by recognizing the compensated temperature based on the detection value of the thermistor detector 55. In particular, in the present invention, the controller 50 performs temperature compensation according to the detection value of the thermistor detector 55 when performing the convection function of the microwave oven. In particular, in the present invention, the temperature compensation value is adjusted differently according to whether the vent motor is driven when the convection function is performed.

In addition, the hood-use microwave oven of the present invention includes a memory 60 that stores a compensation value based on the temperature detected from the thermistor detector 55 when performing the convection function. The memory 60 includes a high temperature compensation value 1 applied when the vent motor 20 is in a stopped state, and a high temperature compensation value 2 applied when the vent motor 20 is in an operating state. Accordingly, the controller 50 controls temperature compensation based on the compensation value stored in the memory 60 based on the detection value of the thermistor detector 55.

The present invention provides a signal input unit 75 for inputting an operation signal according to various functions of a microwave oven, a heater driving unit 65 for driving a heater under the control of the control unit 50 when performing a convection function, Convection fan drive unit 70 is driven by the control of the control unit 50 when performing the convection function to allow convection circulation of heat generated from the heater throughout the cooking chamber. And the display according to the operation state of the microwave oven is made on the display unit 80.

In addition, the vent motor driving unit 85 for driving the vent motor 20 by a control of the controller 50 or by a separate user control signal is included separately from the configuration of the microwave oven.

Next will be described in detail with respect to the temperature compensation method of the microwave oven with hood according to the present invention having the above configuration.

4 is an operation flowchart for temperature compensation when performing a convection function in a hooded microwave oven according to the present invention.

As shown in FIG. 1, the hood-use microwave oven includes a vent motor 20 in the upper portion of the microwave oven. The vent motor 20 performs the same function as the indoor hood. That is, it is used for the purpose of exhausting the smoke | gas generated from the cooking apparatus 30 installed in the lower side of a microwave oven to the outside. Therefore, the vent motor 20 is selectively operated regardless of the driving of the microwave oven.

When the vent motor 20 is driven, as shown in FIG. 1, the smoke from the external cooking device 30 passes through the air flow path between the cooking chamber 10 and the external cavity 15 of the microwave oven. It is discharged to the rear side of the motor 20.

On the other hand, the vent motor 20 is configured to be controlled regardless of the operation of the microwave oven. Therefore, the on / off operation of the vent motor 20 can be controlled even when the microwave oven performs the convection function by the convection circulation and the microwave function by the microwave wave. At this time, the control of the vent motor 20 is driven while the user control signal is directly supplied to the vent motor driver 85.

Next, the microwave oven performs cooking at the user's request. If the dish selected by the user is a dish to perform a convection function, the controller 50 performs selective temperature compensation.

When the user performs the automatic cooking or the manual cooking through the signal input unit 75, the controller 50 determines whether the cooking selected by the user is a cooking which should perform a convection function (step 100).

If the condition of step 100 is not satisfied, the controller 50 ends the temperature compensation control according to the convection function. However, when the condition of step 100 is satisfied, the heater is driven by outputting a drive signal to the heater driver 65. In addition, a driving signal is applied to the convection fan driver 70 to drive the convection fan (step 103). The heat generated by the heater under the control of the 103rd step is supplied to the food while circulating the inside of the cooking chamber with the air circulated to allow cooking.

In this state in which the convection function is performed, the controller 50 reads the temperature detected from the thermistor 25 through the thermistor detector 55 (step 106). The controller 50 determines the temperature according to the state of the current cooking chamber by the temperature read in step 106.

On the other hand, the controller 50 determines whether the vent motor 20 is being driven prior to controlling the cooking by the detection temperature (step 109).

When the vent motor 20 is not driven in step 109, the controller 50 reads the internal temperature compensation value 1 stored in the memory 60 (step 115).

The high temperature compensation value 1 read out at the 115th step is shown in FIG. 5A. That is, the high temperature compensation value 1 shown in FIG. 5A is a compensation value for determining the actual internal temperature according to the detection value of the thermistor 25 when the vent motor is not driven. The error occurs in the detected value of the thermistor 25 and the actual internal temperature of the thermistor 25 due to the installation position of the thermistor, the influence of the air circulated convection in the cooking chamber, the accuracy of the thermistor and the like.

Therefore, the controller 50 recognizes the internal temperature corresponding to the thermistor detection temperature read in step 106 and performs cooking control according to the recognized internal temperature. When the recognized internal temperature reaches the target temperature in this way, the controller 50 outputs a stop signal to the heater driver 65 and the convection fan driver 70 to complete the heating operation according to the convection function (step 118). ).

However, when it is determined in step 109 that the vent motor 20 is being driven, the controller 50 reads the temperature compensation value 2 stored in the memory 60 (step 112).

The internal temperature compensation value 2 read out at the step 112 is shown in FIG. 5B. The high temperature compensation value 2 shown in FIG. 5B detects a relatively low thermistor temperature as compared with the high temperature compensation value 1 shown in FIG. 5A. This indicates that when the convection function is performed while the vent motor 20 is driven, a relatively large difference occurs between the high temperature inside the thermistor 25 and the detection temperature.

Therefore, when the vent motor is driven, the controller 50 performs cooking control according to the temperature compensation value shown in FIG. 5B. When the recognized internal temperature reaches the target temperature in this way, the controller 50 outputs a stop signal to the heater driver 65 and the convection fan driver 70 to complete the heating operation according to the convection function (step 118). ).

As described above, the present invention is characterized in that when performing the convection function, by adjusting the temperature compensation value according to whether the vent motor is driven, a constant internal temperature control can be always performed regardless of the driving of the vent motor.

According to the present invention described above, constant temperature control can be achieved regardless of the operation of the vent motor in the microwave oven that compensates the temperature value differently according to the operating condition of the vent motor, so that the optimum food can be obtained. There is. In addition, the present invention can increase the reliability and quality of the product from the above effects.

Claims (2)

In a microwave oven with a vent motor that is operated independently of the operation of the microwave for the indoor hood function, Setting a temperature compensation value 1 and a temperature compensation value 2 according to whether the vent motor is driven in the convection cooking; Determining whether the vent motor is driven; Detecting an internal temperature of the cooking chamber through the temperature detector; Selecting one of the set temperature compensation values 1 and 2 according to whether the vent motor is driven and performing temperature compensation on the detected temperature according to the selected temperature compensation value. Temperature compensation method. The method of claim 1, The temperature compensation step, the temperature compensation method of the microwave oven with a hood, characterized in that made until reaching the target temperature by cooking.